TY - JOUR
T1 - Understanding Electrical Conduction and Nanopore Formation During Controlled Breakdown
AU - Fried, Jasper P.
AU - Swett, Jacob L.
AU - Nadappuram, Binoy Paulose
AU - Fedosyuk, Aleksandra
AU - Sousa, Pedro Miguel
AU - Briggs, Dayrl P.
AU - Ivanov, Aleksandar P.
AU - Edel, Joshua B.
AU - Mol, Jan A.
AU - Yates, James R.
N1 - Funding Information:
Substrate, membrane, and some of the electrode fabrication was conducted at the Center for Nanophase Materials Sciences, which is a DOE Office of Science User Facility. J.F. thanks the Oxford Australia Scholarship committee and the University of Western Australia for funding. J.Y. was funded by an FCT contract according to DL57/2016, [SFRH/BPD/80071/2011]. Work in J.Y.'s lab was funded by national funds through FCT ‐ Fundação para a Ciência e a Tecnologia, I. P., Project MOSTMICRO‐ITQB with refs UIDB/04612/2020 and UIDP/04612/2020 and Project PTDC/NAN‐MAT/31100/2017. J.M. was supported through the UKRI Future Leaders Fellowship, Grant No. MR/S032541/1, with in‐kind support from the Royal Academy of Engineering. A.I. and J.E. acknowledge support from BBSRC grant BB/R022429/1, EPSCR grant EP/P011985/1, and Analytical Chemistry Trust Fund grant 600322/05. This project has also received funding from the European Research Council (ERC) under the European Union's Horizon 2020 research and innovation programme (grant agreement No 724300 and 875525). The authors would like to thank Andrew Briggs for providing financial support.
Funding Information:
Substrate, membrane, and some of the electrode fabrication was conducted at the Center for Nanophase Materials Sciences, which is a DOE Office of Science User Facility. J.F. thanks the Oxford Australia Scholarship committee and the University of Western Australia for funding. J.Y. was funded by an FCT contract according to DL57/2016, [SFRH/BPD/80071/2011]. Work in J.Y.'s lab was funded by national funds through FCT - Funda??o para a Ci?ncia e a Tecnologia, I. P., Project MOSTMICRO-ITQB with refs UIDB/04612/2020 and UIDP/04612/2020 and Project PTDC/NAN-MAT/31100/2017. J.M. was supported through the UKRI Future Leaders Fellowship, Grant No. MR/S032541/1, with in-kind support from the Royal Academy of Engineering. A.I. and J.E. acknowledge support from BBSRC grant BB/R022429/1, EPSCR grant EP/P011985/1, and Analytical Chemistry Trust Fund grant 600322/05. This project has also received funding from the European Research Council (ERC) under the European Union's Horizon 2020 research and innovation programme (grant agreement No 724300 and 875525). The authors would like to thank Andrew Briggs for providing financial?support.
Publisher Copyright:
© 2021 The Authors. Small published by Wiley-VCH GmbH
PY - 2021/9/16
Y1 - 2021/9/16
N2 - Controlled breakdown has recently emerged as a highly appealing technique to fabricate solid-state nanopores for a wide range of biosensing applications. This technique relies on applying an electric field of approximately 0.4–1 V nm−1 across the membrane to induce a current, and eventually, breakdown of the dielectric. Although previous studies have performed controlled breakdown under a range of different conditions, the mechanism of conduction and breakdown has not been fully explored. Here, electrical conduction and nanopore formation in SiNx membranes during controlled breakdown is studied. It is demonstrated that for Si-rich SiNx, oxidation reactions that occur at the membrane-electrolyte interface limit conduction across the dielectric. However, for stoichiometric Si3N4 the effect of oxidation reactions becomes relatively small and conduction is predominately limited by charge transport across the dielectric. Several important implications resulting from understanding this process are provided which will aid in further developing controlled breakdown in the coming years, particularly for extending this technique to integrate nanopores with on-chip nanostructures.
AB - Controlled breakdown has recently emerged as a highly appealing technique to fabricate solid-state nanopores for a wide range of biosensing applications. This technique relies on applying an electric field of approximately 0.4–1 V nm−1 across the membrane to induce a current, and eventually, breakdown of the dielectric. Although previous studies have performed controlled breakdown under a range of different conditions, the mechanism of conduction and breakdown has not been fully explored. Here, electrical conduction and nanopore formation in SiNx membranes during controlled breakdown is studied. It is demonstrated that for Si-rich SiNx, oxidation reactions that occur at the membrane-electrolyte interface limit conduction across the dielectric. However, for stoichiometric Si3N4 the effect of oxidation reactions becomes relatively small and conduction is predominately limited by charge transport across the dielectric. Several important implications resulting from understanding this process are provided which will aid in further developing controlled breakdown in the coming years, particularly for extending this technique to integrate nanopores with on-chip nanostructures.
KW - dielectric breakdown
KW - nanofabrication
KW - single-molecule biosensing
KW - solid-state nanopores
UR - http://www.scopus.com/inward/record.url?scp=85111865188&partnerID=8YFLogxK
U2 - 10.1002/smll.202102543
DO - 10.1002/smll.202102543
M3 - Article
C2 - 34337856
AN - SCOPUS:85111865188
SN - 1613-6810
VL - 17
JO - Small
JF - Small
IS - 37
M1 - 2102543
ER -